CIPP liner feed roller

ABSTRACT

A CIPP liner feed roller for manipulating and feeding CIPP liner by pulling CIPP liner from a liner source and feeding it to where it is needed. The CIPP liner feed roller generally includes a main roller attached to a frame, a clamping roller attached to the frame and configured to be in parallel with the main roller, wherein the distance between the clamping roller and the main roller can be adjusted using one or more actuators, a drive unit comprising a motor configured to control the rotation of the main roller within the frame, a controller coupled to the drive unit and the one or more actuators, wherein the controller is configured to control the rotation of the main roller and the distance between the clamping roller and the main roller, and a support beam attached the frame and configured to be in parallel with the main roller.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. application Ser. No.15/480,630 filed on Apr. 6, 2017 which issues on Dec. 1, 2020 as U.S.Pat. No. 10,851,933. Each of the aforementioned patent applications, andany applications related thereto, is herein incorporated by reference intheir entirety.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not applicable to this application.

BACKGROUND Field

Example embodiments in general relate to a CIPP liner feed roller forpreparing and inserting CIPP liner into an access opening, includingfolding of the CIPP liner prior to insertion.

Related Art

Any discussion of the related art throughout the specification should inno way be considered as an admission that such related art is widelyknown or forms part of common general knowledge in the field.

Cured-in-place pipe (CIPP) liners have been used for many years for therehabilitation of different types and sizes of conduit and pipingsystems such as utility, sewer, water, electric, telecom, industrial,petroleum, fire suppression, heating, cooling and the like. The majorityof materials used to manufacture these liners is felt and fleece typefabrics which have a thin flexible PVC or Polyurethane type jacketcoating on one side. The liners are usually impregnated with athermosetting type resin then installed by inverting the liner inside ofthe host conduit or pipe with air or water.

Ultraviolet (UV) cured-in-place pipe liner is a recent type of CIPPliner that utilizes UV light to cure the CIPP liner inside of a conduit.UV cured CIPP liners are bulky and relatively heavy to work with.Furthermore, UV cured CIPP liners need to be handled carefully becauseif the outer protective layer is damaged or partially removed, the UVcured CIPP liner will harden within minutes when exposed to sunlight.U.S. Pat. No. 8,580,364 to Quitter illustrates an exemplary UV curedCIPP liner. One advantage of UV cured CIPP liners is they are relativelyenvironmentally friendly compared to traditional CIPP liners that areimpregnated with a thermosetting type resin that can leach into thesurrounding water ways. However, UV cured CIPP liners are typicallythicker and heavier than conventional CIPP liners making it difficult tomaneuver them, particularly through smaller openings.

Prior methods of feeding CIPP liner (including UV cured CIPP liners)into access openings include the use of conveyer belts and single taskdevices. In some cases, the CIPP liner is pulled directly from a truckinto an access opening (e.g. manhole) that is smaller than the width ofthe CIPP liner requiring workers to manually fold the liner upon itselfto fit through the access opening. Such prior methods lackconfigurability and are generally incapable to folding CIPP liner aspart of the feeding process.

SUMMARY

An example embodiment is directed to a CIPP liner feed roller configuredto pull CIPP liner from a liner source and push the CIPP liner to whereit is needed. The CIPP liner feed roller includes a main roller attachedto a frame, and a clamping roller attached to the frame and configuredto be in parallel with the main roller, wherein the distance between theclamping roller and the main roller can be adjusted using one or moreactuators. The combination of the main roller and clamping roller isused to pull the CIPP liner through the CIPP liner feed roller. The CIPPliner feed roller may also include a drive unit comprising a motorconfigured to control the rotation of the main roller within the frameand a controller coupled to the drive unit and the one or moreactuators, wherein the controller is configured to control the rotationof the main roller and the distance between the clamping roller and themain roller. The CIPP liner feed roller may also include a support beamattached to the frame and configured to be in parallel with the mainroller to enable the attachment of various accessories to add or improvethe functionality of the CIPP liner feed roller. These accessoriesinclude, but are not limited to, support legs, guide rollers, a foldingroller assembly, a balance roller, and an infeed table.

There has thus been outlined, rather broadly, some of the embodiments ofthe CIPP liner feed roller in order that the detailed descriptionthereof may be better understood, and in order that the presentcontribution to the art may be better appreciated. There are additionalembodiments of the CIPP liner feed roller that will be describedhereinafter and that will form the subject matter of the claims appendedhereto. In this respect, before explaining at least one embodiment ofthe CIPP liner feed roller in detail, it is to be understood that theCIPP liner feed roller is not limited in its application to the detailsof construction or to the arrangements of the components set forth inthe following description or illustrated in the drawings. The CIPP linerfeed roller is capable of other embodiments and of being practiced andcarried out in various ways. Also, it is to be understood that thephraseology and terminology employed herein are for the purpose of thedescription and should not be regarded as limiting.

BRIEF DESCRIPTION OF THE DRAWINGS

Example embodiments will become more fully understood from the detaileddescription given herein below and the accompanying drawings, whereinlike elements are represented by like reference characters, which aregiven by way of illustration only and thus are not limitative of theexample embodiments herein.

FIG. 1 is a perspective view of a CIPP liner feed roller in accordancewith an example embodiment.

FIG. 2 is an alternate perspective view of a CIPP liner feed roller inaccordance with an example embodiment.

FIG. 3 is a front view of a CIPP liner feed roller in accordance with anexample embodiment.

FIG. 4 is a rear view of a CIPP liner feed roller in accordance with anexample embodiment.

FIG. 5 is a top view of a CIPP liner feed roller in accordance with anexample embodiment.

FIG. 6 is a bottom view of a CIPP liner feed roller in accordance withan example embodiment.

FIG. 7 is a right-side view of a CIPP liner feed roller in accordancewith an example embodiment.

FIG. 8 is a left-side view of a CIPP liner feed roller in accordancewith an example embodiment.

FIG. 9 is a right-side cross-section view of a CIPP liner feed roller inaccordance with an example embodiment.

FIG. 10a is a cross-section view of a support connector and accessoryconnector that have been coupled to a support beam using a connectorbolt.

FIG. 10b is a cross-section of a support connector and accessoryconnector that are in the process of being coupled to a support beamusing a connector bolt.

FIG. 11 is a perspective view of a CIPP liner feed roller in accordancewith an example embodiment that includes support legs, a work platform,and a balance roller.

FIG. 12 is a right-side cross-section view of a CIPP liner feed rollerin accordance with an example embodiment that includes support legs, awork platform, and a balance roller.

FIG. 13 is a perspective view of a CIPP liner feed roller in accordancewith an example embodiment that includes an infeed table and a secondarymaterial holder.

FIG. 14 is an alternate perspective view of a CIPP liner feed roller inaccordance with an example embodiment that includes an infeed table, asecondary material holder, and a balance roller.

FIG. 15 is a left-side cross-section view of a CIPP liner feed roller inaccordance with an example embodiment that includes an infeed table, asecondary material holder, and a balance roller.

FIG. 16 is a right-side view of a left side plate in accordance with anexample embodiment.

FIG. 17 is a front view of a CIPP liner feed roller in accordance withan example embodiment with the interior of the sides of the frameexposed.

FIG. 18 is a rear view of a CIPP liner feed roller in accordance with anexample embodiment with the interior of the sides of the frame exposed.

FIG. 19 is a left-side view of a CIPP liner feed roller in accordancewith an example embodiment that features the left side plate.

FIG. 20 is a left-side view of a CIPP liner feed roller in accordancewith an example embodiment with the left side panel removed.

FIG. 21 is a right-side view of a CIPP liner feed roller in accordancewith an example embodiment with the right side panel removed.

FIG. 22 is a left-side cross-section view of a folding roller assemblyin accordance with an example embodiment.

FIG. 23 is a left-side cross-section view of a CIPP liner feed roller inaccordance with an example embodiment that includes a folding rollerassembly.

FIG. 24 is a perspective view of a CIPP liner feed roller in accordancewith an example embodiment that includes a folding roller assembly.

FIG. 25 is an alternate perspective view of a CIPP liner feed roller inaccordance with an example embodiment that includes a folding rollerassembly.

FIG. 26 is a left-side cross-section view illustrating a CIPP liner feedroller in accordance with an example embodiment being used to insertCIPP liner into an access opening.

FIG. 27 is a left-side cross-section view illustrating a CIPP liner feedroller in accordance with an example embodiment being used to fold CIPPliner and insert the folded CIPP liner into an access opening.

FIG. 28a is a top view illustrating a step in the use of an exampleembodiment of a feed roller assembly being used to fold CIPP liner as itpasses through an example embodiment of a CIPP liner feed roller.

FIG. 28b is a top view illustrating a step in the use of an exampleembodiment of a feed roller assembly being used to fold CIPP liner as itpasses through an example embodiment of a CIPP liner feed roller.

FIG. 28c is a top view illustrating a step in the use of an exampleembodiment of a feed roller assembly being used to fold CIPP liner as itpasses through an example embodiment of a CIPP liner feed roller.

FIG. 28d is a top view illustrating a step in the use of an exampleembodiment of a feed roller assembly being used to fold CIPP liner as itpasses through an example embodiment of a CIPP liner feed roller.

FIG. 29 is a perspective view of an example embodiment of a feed rollerassembly being used to fold CIPP liner as it passes through an exampleembodiment of a CIPP liner feed roller.

FIG. 30 is an alternate perspective view of an example embodiment of afeed roller assembly being used to fold CIPP liner as it passes throughan example embodiment of a CIPP liner feed roller.

DETAILED DESCRIPTION A. Overview

Turning now descriptively to the drawings, in which similar referencecharacters denote similar elements throughout the several views, FIGS. 1through 30 illustrate a CIPP liner feed roller, which comprises a frame20 having a left side and a right side, a main roller 30 attached to theframe 20, a clamping roller 40 attached to the frame 20 and configuredto be in parallel with the main roller 30, wherein the distance betweenthe clamping roller 40 and the main roller 30 can be adjusted using oneor more actuators 42, a drive unit 50 configured to control the rotationof the main roller 30 within the frame 20, a controller 54 coupled tothe drive unit 50 and the actuators 42, wherein the controller 54 isconfigured to control the rotation of the main roller 30 and thedistance between the clamping roller 40 and the main roller 30, and asupport beam 60 attached to the frame 20 and configured to be inparallel with the main roller 30. Some embodiments also includecontroller openings 55 configured to route power and control cablesbetween the controller 54 and the drive unit 50, and the one or moreactuators 42. Some embodiments may also include a passage within thesupport beam 60 that enable the passage of cables between the left sideof the frame 20 and the right side of the frame 20. Some embodimentsinclude a bridge beam 27, a bridge connector 28, and a bridge attachment29 that enable the CIPP liner feed roller to be lifted using a crane.The CIPP liner feed roller is generally configured to pull CIPP liner 10between the main roller 30 and the clamping roller 40 from a linersource, such as a liner box 11, and push the CIPP liner 10 away from theCIPP liner feed roller, which is usually towards an access opening 14.The CIPP liner 11 may be comprised of various types of CIPP linersincluding, but not limited to, UV cured CIPP liners.

B. Frame

FIGS. 1 through 8, 11 through 15, 17 through 21, and 23 through 30illustrate an exemplary frame 20 for a CIPP liner feed roller. The frame20 is generally configured to house a main roller 30, a clamping roller40, one or more actuators 42, a drive unit 50, and a controller 54. Theframe 20 generally comprises a left side plate 21, a left outer panel22, a right side plate 24, a right outer panel 25, a bridge beam 27 anda support beam 60. The frame 20 may also include supplemental structuralsupport, such as a bottom plate 23. The respective left and right sidesof the frame 20 may also include panels to protect any components storedwithin the sides of the frame 20. The frame 20 may include an accesspanel 58 that may be used to route power cables to the CIPP liner feedroller as well as provide for the passage of cables to the operatorcontrols 56.

The left side of the CIPP liner feed roller generally comprises a leftouter panel 22 and a left side plate 21. The left side plate 21 isconfigured to support a main roller 30, a clamping roller 40, a bridgebeam 27, and a support beam 60. The left side plate 21 also includesapertures to support the connection of the various components using nutsand bolts. These apertures could also be used for other attachmentmethods. In addition, the apertures could be threaded to support theinsertion of a bolt directly. As shown in FIG. 16, the left side plate21 comprises a clamping roller slot 44 that permits the left side of theclamping roller 40 to move towards or away from the main roller 30. Theleft side plate 21 may also be configured to support at least oneactuator 42 that is operatively coupled to the clamping roller 40 suchthat the motion of the actuator will move the clamping roller 40 towardsor away from the main roller 30 in the manner defined by the clampingroller slot 44. Although FIG. 16 illustrates the clamping roller slot 44as an arc, other configurations can be used such as a straight slot, forexample. The left side plate 21 also includes support beam openings 61,which provide access to a passage within support beam 60, if present.The left side plate 21 also includes a bridge slot 26, which isconfigured to accept the bridge beam 27.

The right side plate 24 of the CIPP liner feed roller is generallyconfigured to be the mirror image of the left side plate 21. However,this may not be the case, if either the left side plate 21 or the rightside plate 24 is configured to support components that are not needed onboth sides. However, any superfluous openings could also simply be leftunused.

The right side of frame 20 and left side of the frame 20 generallyinclude a left outer panel 22 and a right outer panel 25, respectively.The outer panels 22, 25 provide protection for any equipment containedwithin the respective sides. The sides of the frame 20 may also containouter plates that provide additional mounting surfaces for any suchequipment, such as those shown in FIGS. 20 and 21. These outer platesare directly behind the corresponding outer panel 22 or 25. The leftside of the frame 20 may also include a bottom plate 23 that canmaintain the separation between left side plate 21 and left side panel22, as shown in FIGS. 17, 18 and 25. In other embodiments, structuralsupport can be located at the top of a frame side, or at intermediatelocations between the left side plate 21 and the left outer panel 22.The right side of frame 20 has a similar configuration with a rightouter panel 25, as illustrated in FIGS. 1 and 7, for example.

As shown in FIGS. 1 through 19, for example, the frame 20 generallyincludes a bridge beam 27 that provides additional structural support tothe frame 20, and may also provide a connection for attaching the CIPPliner feed roller to a crane or other lifting device. The bridge beam 27is generally connected to the left side of the frame 20 using a bridgeslot 26 within the left side plate 21 and a complementary bridge slot 26within the right side plate 24. The bridge beam 27 may also include oneor more bridge connectors 28 that can be used to attach one or morebridge attachments 29 to the bridge beam 27. For example, FIGS. 1through 4 illustrate a bridge connector 28 that has been bolted to thecenter of bridge beam 27 and is connected to a small triangular bridgeattachment 29 with a single aperture. In this embodiment, a cord, rope,bolt or rod could be passed through the aperture to aid lifting the CIPPliner feed roller using a crane. In other embodiments, the bridgeattachment 29 may comprise multiple apertures or include any ancillaryattachment requirements.

The frame 20 generally includes a support beam 60 that is connected tothe left side plate 21 and the right side plate 24. In otherembodiments, the support beam 60 may pass through the left side plate 21and the right side plate 24 and be connected to the respective outerplates or outer panels 22, 25.

C. Main Roller

As best shown in FIG. 1, the CIPP liner feed roller generally comprisesa main roller 30 that is connected to frame 20 and is coupled to a driveunit 50. The main roller 30 is attached to the left side plate 21 andthe right side plate 24 in a manner that permits it to rotate relativeto the frame 20 as directed by the drive unit 50. The drive unit 50 cangenerally control the direction that the main roller 30 rotates as wellas the speed of its rotation. The main roller 30 generally comprises ahigh friction outer surface that tends to couple the motion of the CIPPliner 10 with the rotation of the main roller 30. In other words, themain roller 30 tends to pull the CIPP liner 10 in the direction of itsrotation. In this embodiment, the main roller 30 generally spans the gapbetween the left side plate 21 and the right side plate 24. In otherembodiments, the main roller 30 only partially spans this gap, orextends beyond the two side plates 21, 24 into the sides of frame 20.

D. Clamping Roller

As best shown in FIG. 2, the CIPP liner feed roller generally comprisesa clamping roller 40 that is connected to the left side plate 21 and theright slide plate 24. The clamping roller 40 is mounted in parallel tothe main roller 30 and is configured in a manner that permits thespacing between the clamping roller 40 and the main roller 30 to beadjusted. This is generally controlled by one or more actuators 42 thatcause the clamping roller 40 to move within a clamping roller slot 42contained within left side plate 21 or right side plate 24, as shown inFIG. 19. Generally, the clamping roller 40 is configured to permit itsspacing to vary between minimal contact with the main roller 30 and themaximum expected thickness of CIPP liner 10 to be fed through the CIPPliner feed roller. However, if the left side plate 21 and right sideplate 24 are configured to accommodate multiple sizes of main rollers 30and clamping rollers 40, the spacing may have different operationallimits.

The clamping roller 40 generally comprises a high friction outer surfacethat tends to couple the rotation of the clamping roller 40 with themotion of CIPP liner 10 in contact with it. However, the clamping roller40 is generally configured to passively rotate relative to the frame 20.In other words, the clamping roller 40 is driven by the motion of theCIPP liner 10 as opposed to driving the motion of the CIPP liner 10.However, because the motion of CIPP liner 10 is controlled by the mainroller 30, the clamping roller 40 can also be considered to be driven bythe main roller 30 as well. Although this embodiment utilizes a passiveclamping roller 40, other embodiments of a CIPP liner feed roller mayuse a clamping roller 40 that actively controls the motion of CIPP liner10 in conjunction with or in lieu of main roller 30.

During operation, CIPP liner 10 is pressed between the clamping roller40 and the main roller 30. This increases the friction between the CIPPliner 10 and the main roller 30 which improves the ability of the mainroller 30 to control the motion of CIPP liner 10. This also acts tocompress CIPP liner 10 as it is fed through the CIPP liner feed roller,which will tend to crease any folds within CIPP liner 10 and/or smoothout any undesirable folds or other surface characteristics of CIPP liner10. The precise pressure between the clamping roller 40 and main roller30 can be adjusted by actuators 42 in accordance with the needs of theparticular task performed by CIPP liner feed roller.

In other embodiments of a CIPP liner feed roller, both the clampingroller 40 and main roller 30 may be moved by actuators. In otherembodiments, the clamping roller 40 may include springs, suspensions, orother components that affect the position of the clamping roller 40.This effect may be applied directly to the clamping roller 40 orindirectly via one or more of the actuators 42. In some embodiments, theclamping roller 40 or actuators 42 include one or more switches orsensors that affect the movement of the clamping roller 40.

E. Support Beam

As shown in FIGS. 1 through 15 and 17 through 30, a CIPP liner feedroller generally includes a support beam 60 that spans the gap betweenthe left side of the frame 20 and right side of frame 20. The supportbeam 60 is generally configured to be in parallel with the main roller30 and clamping roller 40. This configuration aids the attachment ofaccessories that interact with CIPP liner 10 as it is fed into or fedout of the CIPP liner feed roller. In one embodiment, the support beam60 is configured below the main roller 30 and clamping roller 40.However, the support beam 60 is not limited to this location. Thesupport beam 60 generally has a uniform cylindrical shape that enablesaccessories attached to the support beam 60 to be repositioned along itslength as well as rotated around its central axis. However, a supportbeam 60 with a different geometric configuration would still be suitablefor use with a CIPP liner feed roller.

The support beam 60 generally contains a passage that permits therouting of cables from the left side of the frame 20 to the right sideof the frame 20. This passage in the support beam 60 permits the routingof power and/or control signals between the sides of the CIPP liner feedroller without exposing any such cables or wires to the outsideenvironment.

F. Accessories

The support beam 60 is configured to permit the attachment of one ormore accessories to the CIPP liner feed roller. These accessories mayadd functionality to the CIPP liner feed roller, such as the ability tooperate free-standing. These accessories may alter the functionality ofthe CIPP liner feed roller, such as modifying the manner in which theCIPP liner 10 flows into or out of the CIPP liner feed roller.

Accessories are generally attached to the CIPP liner feed roller usingthe combination of a support connector 62 and an accessory connector 64.FIGS. 10a and 10b illustrate an embodiment of a support connector 62 andan accessory connector 64 that are configured to allow the attachment ofan accessory to a cylindrical support beam 60. The accessory shown inFIGS. 10a and 10b is a secondary material holder 74, but the samegeneral concepts apply to other accessories as described herein. To theextent that the support beam 60 does not have a cylindrical shape, thesupport connector 62 and accessory connector 64 will have acomplementary shape that enables attachment to it. The coupling of theaccessory connector 64 and support connector 62 is not limited to theuse of hooks, such as the support connector hook 63 and accessoryconnector hook 65.

In one embodiment, the support connector 62 comprises a supportconnector hook 63 and a support connector opening 80 configured toreceive a connector bolt 82. The support connector hook 63 is configuredto interlock with an accessory connector hook 65 on an accessoryconnector 64. The coupling of the accessory connector 64 and supportconnector 62 is not limited to the use of hooks, such as supportconnector hook 63 and accessory connector hook 65. Although, theaccessory connector 64 shown in FIGS. 10a and 100b is an integral partof secondary material holder 74, the portion that is nearest the supportconnector 62 and support beam 60 can be considered the accessoryconnector 64. In addition to accessory connector hook 65, the accessoryconnector 64 generally comprises an accessory connector opening 81 thatis configured to threadably attach to a connector bolt 82 that isdisposed within the support connector opening 80.

As shown in FIG. 10b , the accessory connector 64 and the supportconnector 62 are generally two separated pieces. A secondary materialholder 74 can be attached to a support beam 60 by interlocking hooks 63,65 around the circumference of the support beam 60. In this embodimentof attaching an accessory to the support beam 60, a curved portion ofthe accessory connector 64 is placed in contact with the support beam60. The support connector 62 is then coupled to the support beam 60 andaccessory connector 64 by interlocking the support connector hook 63with the accessory connector hook 65. The support connector 62 can thenbe fitted around the support beam 60, such that the accessory connectoropening 81 and the support connector opening 80 are aligned. Once theopenings 80, 81 are aligned, a connector bolt 82 can be fed through thesupport connector opening 80 and screwed into accessory connectoropening 81.

The strength of the connection between the accessory connector 64, thesupport connector 62 and the support beam 60 is controlled by thetightening or loosening of the connector bolt 82. Thus, when theconnector bolt 82 is sufficiently tightened, the connectors 62, 64 areprevented from sliding along the length of the support beam 60 orrotating around its central axis. However, if the connector bolt 82 issufficiently loosened, the connectors 62, 64 can be repositioned on thesupport beam 60 (sliding or rotating) without being detaching from eachother or the support beam 60. In some embodiments, the support connector62 and the accessory connector 64 contain a high-friction surface on theportions that contact support beam 60.

The accessory connector 64 shown in FIGS. 10a and 10b can be used as abasis for other accessories, including, but not limited to, those shownin FIGS. 11 through 15. In some embodiments, the shape of the supportconnector 62 is the same for all accessories. In these embodiments, allaccessories will use the same shape for accessory connector 64. In otherembodiments, each accessory may utilize a different support connector 62that is configured to couple only with that particular accessory. Suchdifferences might include the circumference distribution of theconnectors 62, 64 around the support beam 60. In FIGS. 10a and 10b , thecircumference of the support beam 60 is roughly split evenly between theconnectors 62, 64. However, a different split is also suitable for usewith the support beam 60. In some embodiments, the combination of thesupport connector 62 and the accessory connector 64 does not span theentire circumference of the support beam 60. Furthermore, the accessoryconnector 64 and support connector 62 may be comprised of multiplepieces that collectively provide attachment to the support beam 60.Moreover, when multiple accessories are used simultaneously, it ispossible for each accessory to use different accessory connectors 64 andsupport connectors 62 yet still be compatible with each other and thesupport beam 60.

Some accessories utilize connector wheels 68, as shown in FIG. 9. Theconnector wheels 68 are intended to passively rotate when in contactwith the main roller 30 and serve to create a minimum separation betweenan accessory and the main roller 30. This is generally the case foraccessories that interact directly with CIPP liner 10 before or after itis fed through the CIPP liner feed roller. The use of connector wheels68 may also apply to accessories that are sufficiently close to the mainroller 30 that there is a significant risk of unintentional contact. Inlieu of or in conjunction with connector wheels 68, inadvertent contactwith a moving part of the CIPP liner feed roller could includemechanical structures that contact other portions of the CIPP liner feedroller.

A guide roller 70 is an example of an accessory that can be used withCIPP liner feed roller. FIG. 9 illustrates one embodiment of a guideroller 70 that includes connector wheels 68. Generally, guide rollers 70control the position of CIPP liner 10 as it is being fed into or fed outof the CIPP liner feed roller. For example, if the CIPP liner feedroller is being used to fold CIPP liner 10, guide rollers 70 on theoutflow side of CIPP liner feed roller can be used to maintain thelateral alignment of folded CIPP liner 10 relative to the main roller30. Generally, this will be aligned with the center of the main roller30. Guide rollers 70 can be used to prevent CIPP liner 10 fromcontacting the left side plate 21 and the right side plate 24. Guiderollers 70 can also be used to direct the outflow of CIPP liner 10 adesired location. As shown in FIGS. 14 and 15, guide rollers 70 can berotated around the central axis of the support beam 60 to accommodatethe CIPP liner 10 that is being pushed out of the CIPP liner feed rollerin a downwards direction. Because of their adjustable rotation, guiderollers 70 generally include connector wheels 68 to prevent inadvertentcontact with the main roller 30.

Support legs 71 are another example of an accessory that can used withthe CIPP liner feed roller. As shown in FIGS. 11 and 12, support legs 71are generally configured to support the weight of the CIPP liner feedroller, including any accessories that might be attached. In addition tothe weight of the CIPP liner feed roller, support legs 71 are generallyconfigured to account for any forces caused by the process of feedingCIPP liner 10 through the CIPP liner feed roller. For example, rotationof the main roller 30 in one direction will exert a rotational force onframe 20 in the opposite direction. To prevent the frame 20 fromactually rotating in response to the rotation of the main roller 30, thesupport legs 71 should accommodate this force. Support legs 71 aregenerally comprised of an accessory connector 64 attached to two legsarranged at an angle. The support legs 71 shown in FIG. 11 are designedto work in a pair with one set of support legs 71 adjacent to the leftside plate 21 and another set of support legs 71 adjacent to the rightside plate 24. In other embodiments, support legs 71 can be comprised ofa single structure. In other embodiments, support legs 71 are located atintermediate positions that are not adjacent to either the right sideplate 24 or the left side plate 21. Such intermediate positions may bein addition to or in lieu of support legs 71 located next to a left sideplate 21 or right side plate 24.

An infeed table 72 is another example of an accessory that can be usedwith the CIPP liner feed roller. As shown in FIG. 15, the infeed table72 controls the angle and shape of CIPP liner 10 as it is pulled intothe CIPP liner feed roller. In general, the infeed table 72 causes CIPPliner 10 to be fed into the CIPP liner feed roller from the side asopposed to from below. The infeed table 72 also tends to flatten out theCIPP liner 10 before it is pulled into the CIPP liner feed roller. Forexample, as shown in FIG. 26, when the CIPP liner 10 is being fed from aliner box 11 that is at a lower elevation than the CIPP liner feedroller, the infeed table 72 forces the CIPP liner 10 to contact the mainroller 30 at a higher angle. The infeed table 72 may also be used inconjunction with guide rollers 70 to further control the infeedcharacteristics of the CIPP liner 10.

As shown in FIGS. 22 through 25, a folding roller assembly 90 is anotherexample of an accessory that can be used with the CIPP liner feedroller. In some embodiments, the CIPP liner 10 is fed out of the CIPPliner feed roller with its sides folded inward. A folding rollerassembly 90 aids in the process of folding the CIPP liner 10 as it isbeing fed out of the CIPP liner feed roller. By curling the ends of CIPPliner 10 before it reaches the main roller 30 and clamping roller 40,the process of pushing out folded CIPP liner 18 encounters fewer errors.

The folding roller assembly 90 generally comprises a folding roller base91 with three pairs of folding rollers: a first set folding rollers 92,a second set of folding rollers 93, and a third set of folding rollers94. In the embodiment shown in FIGS. 22 through 25, the three sets offolding rollers 92, 93, 94 are at three different angles relative to themain roller 30 with each member of a set of folding rollers being amirror image of the other. The folding roller assembly 90 also includestwo sets of horizontal rollers: inflow horizontal rollers 95 and outflowhorizontal rollers 96 that are configured to be in parallel to the mainroller 30.

The inflow horizontal rollers 95 support CIPP liner as it passes throughthe folding roller assembly 90 to ensure that it contacts and ismodified by the sets of folding rollers 92, 93, 94. Each member of thefirst set of folding rollers 92 is generally tilted upwards and towardseach other at an angle that is between parallel with the main roller 30(0 degrees) and perpendicular with the main roller 30 (90 degrees). Eachmember of the first set of folding rollers 92 is usually tilted upwardsat the same angle as the other relative to parallel with the main roller30. The first set of rollers 92 generally curls the ends of the CIPPliner 10 and keeps it within certain boundaries. Each member of thesecond set of folding rollers 93 is generally tilted further towardseach other than the corresponding member of the first set of foldingrollers 92. Each member of the second set of folding rollers 93 may beconfigured to be perpendicular with the main roller 30. Each member ofthe second set of folding rollers 93 is usually tilted at the same angleas the other relative to parallel with the main roller 30. The secondset of folding rollers 93 adds additional curl to the curl caused by thefirst set of rollers 92. Each member of the third set of folding rollers94 is generally tilted further towards each other than the correspondingmember of the second set of folding rollers 93. Each member of the thirdset of folding rollers 94 is generally titled towards each other at anangle that is between perpendicular with the main roller 30 (90 degrees)and parallel with the main roller 30 (180 degrees). Each member of thethird set of folding rollers 94 is usually tilted at the same angle asthe other relative to parallel with the main roller 30. The third set offolding rollers 94 generally pushes the edges of the CIPP Liner 10downwards to create the beginnings of a fold in the CIPP liner 10.

The folding roller assembly 90 shown in FIGS. 22 through 25 is a unitarystructure that incorporates two accessory connectors 64 that areconnected to two support connectors 62. In other embodiments, thefolding roller assembly 90 may have a single point of attachment or morethan two. Different embodiments of the folding roller assembly 90 mayalso include a different configuration of folding rollers 92, 93, 94.Other embodiments of the folding roller assembly 90 utilize sets offolding rollers 92, 93, 94 wherein each member does not have the sameangle as the other relative to parallel with the main roller 30. Forexample, if the CIPP liner 10 is to be folded in half, one member of apair of folding rollers 92, 93, 94 may tilt inwards with the othermember being perpendicular to the main roller 30. Furthermore, a greaternumber of folding rollers might be employed to further curl the CIPPliner 10 before it contacts the main roller 30, or curl the CIPP liner10 more gradually.

The CIPP liner feed roller shown in FIGS. 11, 12, 14, 15, and 26includes a balance roller 73. The balance roller 73 can be used tomodify the direction of the CIPP liner 10 after it has been fed throughthe CIPP liner feed roller. For example, as shown in FIG. 26, inapplications where the CIPP liner 10 will be fed into an access opening14 below the elevation of the main roller 30, the balance roller 73 canbe used to avoid having the outflow of CIPP liner 10 pull directly downon the main roller 30. This reduces the tendency for the CIPP liner feedroller to tip over and provides better control over the position of theoutflow of CIPP liner 10. Generally, the balance roller 73 contains apassive roller with a high friction surface. As shown in FIG. 15, therotation of the balance roller 73 along the central axis of the supportbeam 60 can be adjusted.

Other accessories that can be used with the CIPP liner feed rollerinclude, but are not limited to, a secondary material holder 74 and awork platform 75. Embodiments including a work platform 75 are shown inFIGS. 11 and 12. Embodiments including a secondary material holder 74are shown in FIGS. 13 through 15. Accessories for use with the CIPPliner feed roller, including, but not limited to, those described abovecan be used individually or in combination with other accessories. Thesupport beam 60 is not inherently limited to a specific number or typeof accessory connectors 64. For example, the embodiment shown in FIG. 15includes an infeed table 72, guide rollers 70, a balance roller 73, anda secondary material holder 74. In addition to the accessories shown,the embodiment shown in FIG. 15 may also be able to accommodate supportlegs 71. To the extent that there is space along the length of thesupport beam 60 and sufficient clearance between other accessories andthe CIPP liner feed roller itself, additional accessories can be usedwith the CIPP liner feed roller.

G. Drive Unit

The drive unit 50 generally includes a motor 51 and a controller 54. Thedrive unit 50 is coupled to the main roller 30 to control the rotationof the main roller 30. In one embodiment, the motor 51 is coupled to themain roller 30 using a chain 34 and a sprocket 32. The sprocket 32 isoperatively coupled to the main roller 30 such that rotation of thesprocket 32 causes rotation of the main roller 30. The drive unit 50 iscoupled to the controller 54, which receives signals from operatorcontrols 56 and sends signals to the motor 51 and actuators 42 tocontrol the rotation of the main roller 30 and the position of theclamping roller 40. In some embodiments, the motor 51 is coupled to aspeed reducer 53.

In some embodiments, the drive unit 50 comprises a hydraulic motor. Inother embodiments, the drive unit 50 comprises a variable speed breakingelectric motor 51. In other embodiments, the drive unit 50 comprises acombination of electrical and hydraulic components. In otherembodiments, a belt or series of gears is used in place of sprocket 32and chain 34.

H. Controller

The CIPP liner feed roller generally comprises a controller 54configured to receive signals from an operator and control the operationof inter alia drive unit 50, and one or more actuators 42. Thecontroller 54 may be disposed within an enclosure and include one ormore controller openings 55, which enable the routing of power orcontrol signals into and out of the controller 54. These controlleropenings 55 can be used to feed power to accessories or otherattachments, such as area lighting.

If the controller 54 is configured to manage equipment on the oppositeside of frame 20, cables can be routed through a passage in support beam60. As shown in FIG. 21, the controller 54 is coupled to the motor 51and an actuator 42 using a motor control cable 52 and an actuator cable43. By routing power and control using controller 54 this enables easyimplementation of an emergency shutoff switch to quickly shutdown allcomponents of the CIPP liner feed roller. The controller 54 may alsoinclude any transformers, signal conditioners, transmitters andreceivers. The controller 54 may also be coupled to a power source usinga reel 59 which helps manage power cords. Power cords and remote cablescan be configured to pass through access panel 58, or other openings orconnection points.

The CIPP liner feed roller is generally coupled to a set of operatorcontrols 56. In some embodiments, the operator controls 56 are coupledto the controller 54 using a cord that passes through the access panel58. The operator controls 56 generally include the ability to controlthe rotation speed and direction of main roller 30, the position of theclamping roller 40 through the actuators 42, and an emergency shutoffswitch. The operator controls 56 may be located remotely, or affixed tothe side of the CIPP liner feed roller. The operator controls 56 mayalso be coupled to the controller 54 using wireless communication. Insome cases, the operator controls 56 may be at least partially redundantallowing for a remote emergency shutdown switch as well as an emergencyshutdown switch located on the CIPP liner feed roller itself.

I. Operation of Preferred Embodiment

One preferred embodiment can be used for the task of pulling folded CIPPliner 10 into an access opening 14, as shown in FIG. 26. Forillustrative purposes, the CIPP liner feed roller shown in FIG. 26 doesnot include a means of support, such as support legs 71 or craneconnected to bridge attachment 29. However, for purposes of thisdescription of a preferred embodiment, the CIPP liner feed roller it ispresumed that it is supported in a way that does not interfere with itsperformance of the exemplary task described herein.

In this exemplary task, as shown in FIG. 26, the CIPP liner 10 will bepulled using a pulling cable 13 into a conduit 16 via an access opening14 with the assistance of a CIPP liner feed roller. For purposes of thisexample, it is assumed that the CIPP liner feed roller can beconveniently located in the immediate vicinity of the access opening 14into which the CIPP liner 10 will be inserted. The CIPP liner 10 will bepulled from a liner box 11 that is on the ground at an elevation belowthat of the CIPP liner feed roller. In this embodiment, the accessopening 14 is also located below the elevation the CIPP liner feedroller.

The first step in this embodiment is to configure the CIPP liner feedroller with the desired accessories and configuration for this exemplarytask. In this embodiment, the CIPP liner feed roller will include aninfeed table 72, a supplemental material holder 74, a balance roller 73,and a pair of guide rollers 70 on the outflow. The guide rollers 70 areattached to the support beam 60 on the outflow side of the CIPP linerfeed roller. In this embodiment, the guide rollers 70 are positionedsuch that the space between them is substantially the same as the widthof the CIPP liner 10. The space between the guide rollers 70 is alignedwith the center of the main roller 30. To minimize stress on the CIPPliner 10, the infeed table 72 is positioned such that the CIPP liner 10leaves the liner box 11 at the same approximate elevation as the lowestend of the infeed table 72. The balance roller 73 is positioned at thesame approximate angle as the infeed table 72 and directly above theaccess opening 14. This position reduces the likelihood that the CIPPliner 10 will contact the sides of the access opening 14.

Once the CIPP liner feed roller has been configured, the next step is toprepare the CIPP liner 10 for insertion using the CIPP liner feedroller. This generally involves separating the clamping roller 40 andthe main roller 30 using the actuators 42, pulling the free end of theCIPP liner 10 through the gap between the rollers 30, 40, and pressingthe CIPP liner 10 by lowering the clamping roller 40 against the mainroller 30. Because this embodiment uses the infeed table 72, guiderollers 70, and the balance roller 73, initial preparation will includeinsuring that the CIPP liner 10 follows the desired pathway. In thisexemplary task, the desired pathway comprises having the CIPP liner 10slide over infeed table 72, rolling over the balance roller 73 betweenthe guide rollers 70, and into the access opening 14. Using the operatorcontrols 56, the CIPP liner feed roller can be operated at slow speedsto test initial configuration so that appropriate adjustments can bemade, if necessary. Once the CIPP liner 10 has been properly configuredin the CIPP liner feed roller, the free end is attached to pulling cable13, and is then inserted into the access opening 14.

The actual insertion process generally comprises pulling the CIPP liner10 through the conduit 16 using a pulling cable 13. In order to avoidexcess contact with the sides of the access opening 14 or the entry intothe conduit 16, the CIPP liner feed roller will feed the CIPP liner 10so as to maintain slack in the CIPP liner 10, which will generally feedthe CIPP liner 10 out at the same rate that the CIPP liner 10 is beingpulled through the conduit 16. In addition, by pressing the CIPP liner10 between the main roller 30 and the clamping roller 40, the CIPP linerfeed roller will tend to flatten any folds in the CIPP liner andstraighten any kinks in the CIPP liner 10. For example, the CIPP liner10 may be stored within a liner box 11 using accordion folds. The CIPPliner feed roller will at least partially flatten these folds before theCIPP liner 10 is inserted into the access opening 14. Guide rollers 70will help maintain the alignment of the CIPP liner 10 to avoid potentialfeed errors. This process will continue until the desired amount of CIPPliner 10 has been inserted into the conduit 16. Any remaining portion ofthe CIPP liner 10 can then be cut off and sealed. Once the remainingportion of the CIPP liner 10 has been prepared for retrieval, the mainroller 30 can be driven in reverse to extract this excess portionthrough the access opening 14 and towards the liner box 11.

In an additional exemplary task, as shown in FIG. 27, the task describedabove will be modified such that folded CIPP liner 18 will be insertedinto the conduit 16 rather than unfolded CIPP liner 10. Moreover, thefolded CIPP liner 18 will be comprise two folds on either end as shownin FIG. 30.

The CIPP liner feed roller configuration for this task shall include afolding roller assembly 90 and guide rollers 70. The folding rollerassembly 90 is attached to the support beam 60 on the inflow side of theCIPP liner feed roller. In this preferred embodiment, the folding rollerassembly 90 is configured with three pairs of folding rollers: 92, 93,94 that are progressively tilted inwards. The center of the feed rollerassembly 90 is aligned with the center of the main roller 30. The guiderollers 70 are attached to the support beam 60 on the outflow side ofthe CIPP liner feed roller. In this embodiment, the guide rollers 70 arepositioned such that the space between them is substantially the same asthe width of the folded CIPP liner 10, which should be slightly morethan half of the width of unfolded CIPP liner 10. The space between theguide rollers 70 is aligned with the center of the main roller 30 andconsequently the center of the feed roller assembly 76.

After the CIPP liner feed roller has been configured for this additionalexemplary task, the CIPP liner 10 can be prepared for insertion. FIG.28a illustrates the exemplary configuration of the CIPP liner feedroller prior to preparation of CIPP liner 10. As shown in FIG. 28b , onestep in preparing the CIPP liner 10 for insertion includes creatingstarter folds on the corners of CIPP liner 10. For this exemplary task,creating a starter fold includes curling and folding the free end of theCIPP liner 10. As shown in FIG. 28c , the free end of the CIPP liner 10is passed through the folding roller assembly 90 and between the mainroller 30 and the clamping roller 40. The folded end is inserted aboveinflow horizontal rollers 95 and between the sets of folding rollers 92,93, 94. Then, the clamping roller 40 is lowered such that the free endof the CIPP liner 10 is folded and firmly pressed between the mainroller 30 and the clamping roller 40. Using the operator controls 56,the main roller 30 can be rotated slowly to create a first portion offolded CIPP liner 18 as shown in FIG. 28d . The folded free-end of theCIPP liner 18 is fed over the outflow horizontal rollers 96 and betweenthe guide rollers 70. If needed, the angles and positions of the guiderollers 70 are adjusted such that the folded CIPP liner 18 will bedirected towards the access opening 14. Once the CIPP liner 10 has beenproperly configured within the feed roller, a pulling cable 13 isattached to the free end of the folded CIPP liner 18. FIGS. 29 and 30illustrate a CIPP liner feed roller that has been prepared to feedfolded CIPP liner 18 through the CIPP liner feed roller.

As described above, the CIPP liner 10 is fed through the folding rollerassembly 90, which causes it to curl before it reaches the main roller30. This preliminary curling of the CIPP liner 10 will improve thefolding process of the main roller 30 and clamping roller 40. Becausethe CIPP liner 10 begins in a liner box 11 at a lower elevation than theCIPP liner feed roller, incoming CIPP liner 10 will initially contactthe inflow horizontal rollers 95 on the folding roller assembly 90,which ensures that the CIPP liner 10 is curled by the folding rollers92, 93, 94 as opposed to passing beneath them. The main roller 30 andthe clamping roller 40 completes the fold as it passes between them. Theguide rollers 70 on the outflow side maintain the alignment of thefolded CIPP liner 18, which prevents folded CIPP liner 18 from unfoldingimmediately after it leaves the CIPP liner feed roller. Just as withunfolded CIPP liner 10, the feed rate of the CIPP liner feed rollerwould preferably match the rate at which the folded CIPP liner 18 isbeing pulled into the conduit 16. This process should be able tocontinue until the needed amount of CIPP liner 10 has been fed throughthe CIPP liner feed roller. However, if problems occur, the CIPP linerfeed roller can be operated in the reverse direction to correct anyerrors before resuming normal operation.

Unless otherwise defined, all technical and scientific terms used hereinhave the same meaning as commonly understood by one of ordinary skill inthe art to which this invention belongs. Although methods and materialssimilar to or equivalent to those described herein can be used in thepractice or testing of the CIPP liner feed roller, suitable methods andmaterials are described above. All publications, patent applications,patents, and other references mentioned herein are incorporated byreference in their entirety to the extent allowed by applicable law andregulations. The CIPP liner feed roller may be embodied in otherspecific forms without departing from the spirit or essential attributesthereof, and it is therefore desired that the present embodiment beconsidered in all respects as illustrative and not restrictive. Anyheadings utilized within the description are for convenience only andhave no legal or limiting effect.

What is claimed is:
 1. A CIPP liner feed roller apparatus, comprising: aframe; a main roller attached to the frame; a clamping roller attachedto the frame and configured to be in parallel with the main roller; adrive unit connected to the main roller, wherein the drive unit isconfigured to rotate the main roller; a controller coupled with thedrive unit, wherein the controller is configured to control the driveunit; a bridge beam attached to the frame; and a bridge connectorattached to the bridge beam; wherein the CIPP liner feed rollerapparatus can be lifted using the bridge connector or an attachmentthereto; and wherein the CIPP liner feed roller apparatus is configuredto pull a CIPP liner between the main roller and the clamping rollerfrom a liner source and push the CIPP liner away from the main rollerand the clamping roller.
 2. The CIPP liner feed roller apparatus ofclaim 1, including a support beam attached to the frame and configuredto be in parallel with the main roller.
 3. The CIPP liner feed rollerapparatus of claim 2, further comprising one or more guide rollersattached to the support beam configured to guide the CIPP liner beforeit is pulled between the main roller and the clamping roller.
 4. TheCIPP liner feed roller apparatus of claim 2, further comprising one ormore guide rollers attached to the support beam configured to guide theCIPP liner after it is has been pushed away from the main roller and theclamping roller.
 5. The CIPP liner feed roller apparatus of claim 2,further comprising a balance roller attached to the support beam andwherein the balance roller is configured in parallel to the main rollerand is positioned to contact the CIPP liner after it has been pushedaway from the main roller and the clamping roller.
 6. The CIPP linerfeed roller apparatus of claim 2, further comprising a plurality offolding rollers configured to curl the CIPP liner before it is pulledbetween the main roller and the clamping roller, wherein the pluralityof folding rollers are attached to the support beam.
 7. The CIPP linerfeed roller apparatus of claim 6, wherein the CIPP liner feed rollerapparatus is configured to push the CIPP liner away from the main rollerand the clamping roller such that the CIPP liner will contain at leastone fold.
 8. The CIPP liner feed roller apparatus of claim 1, includingat least one actuator connected to the clamping roller, wherein adistance between the clamping roller and the main roller can be adjustedusing the at least one actuator, wherein the CIPP liner is pressedbetween the clamping roller and the main roller when the clamping rolleris moved toward the main roller.
 9. The CIPP liner feed roller apparatusof claim 8, wherein the at least one actuator is comprised of a firstactuator and a second actuator, wherein the first actuator is attachedto a first end of the clamping roller and the second actuator isattached to a second end of the clamping roller.
 10. The CIPP liner feedroller apparatus of claim 1, including one or more springs connected tothe clamping roller.
 11. The CIPP liner feed roller apparatus of claim1, wherein the controller is coupled with the drive unit via a cable orwireless communication.
 12. A CIPP liner feed roller apparatus,comprising: a frame; a main roller attached to the frame; a clampingroller attached to the frame and parallel with the main roller; at leastone actuator or at least one spring connected to the clamping roller,wherein a distance between the clamping roller and the main roller canbe adjusted using the at least one actuator or the at least one spring;a drive unit connected to the main roller, wherein the drive unit isconfigured to rotate the main roller; a controller coupled with thedrive unit via a cable or wireless communication, wherein the controlleris configured to control the drive unit; a bridge beam attached to theframe; and a bridge connector attached to the bridge beam; wherein theCIPP liner feed roller apparatus can be lifted using the bridgeconnector or an attachment thereto; and wherein the CIPP liner feedroller apparatus is configured to pull a CIPP liner between the mainroller and the clamping roller from a liner source and push the CIPPliner away from the main roller and the clamping roller.
 13. The CIPPliner feed roller apparatus of claim 12, including a support beamattached to the frame and configured to be in parallel with the mainroller.
 14. The CIPP liner feed roller apparatus of claim 13, furthercomprising one or more guide rollers attached to the support beamconfigured to guide the CIPP liner before it is pulled between the mainroller and the clamping roller.
 15. The CIPP liner feed roller apparatusof claim 13, further comprising one or more guide rollers attached tothe support beam configured to guide the CIPP liner after it is has beenpushed away from the main roller and the clamping roller.
 16. The CIPPliner feed roller apparatus of claim 13, further comprising a balanceroller attached to the support beam and wherein the balance roller isconfigured in parallel to the main roller and is positioned to contactthe CIPP liner after it has been pushed away from the main roller andthe clamping roller.
 17. The CIPP liner feed roller apparatus of claim13, further comprising a plurality of folding rollers configured to curlthe CIPP liner before it is pulled between the main roller and theclamping roller, wherein the plurality of folding rollers are attachedto the support beam.
 18. The CIPP liner feed roller apparatus of claim17, wherein the CIPP liner feed roller apparatus is configured to pushthe CIPP liner away from the main roller and the clamping roller suchthat the CIPP liner will contain at least one fold.
 19. The CIPP linerfeed roller apparatus of claim 13, wherein the at least one actuator iscomprised of a first actuator and a second actuator, wherein the firstactuator is attached to a first end of the clamping roller and thesecond actuator is attached to a second end of the clamping roller. 20.A CIPP liner feed roller apparatus, comprising: a frame; a main rollerattached to the frame; a clamping roller attached to the frame andparallel with the main roller; a first actuator and a second actuator,wherein the first actuator is attached to a first end of the clampingroller and the second actuator is attached to a second end of theclamping roller, wherein a distance between the clamping roller and themain roller can be adjusted using the first actuator and the secondactuator; a drive unit connected to the main roller, wherein the driveunit is configured to rotate the main roller; a controller coupled withthe drive unit via a cable or wireless communication, wherein thecontroller is configured to control the drive unit; a bridge beamattached to the frame; and a bridge connector attached to the bridgebeam; wherein the CIPP liner feed roller apparatus can be lifted usingthe bridge connector or an attachment thereto; and wherein the CIPPliner feed roller apparatus is configured to pull a CIPP liner betweenthe main roller and the clamping roller from a liner source and push theCIPP liner away from the main roller and the clamping roller.
 21. TheCIPP liner feed roller apparatus of claim 20, including a support beamattached to the frame and configured to be in parallel with the mainroller.
 22. The CIPP liner feed roller apparatus of claim 21, furthercomprising one or more guide rollers attached to the support beamconfigured to guide the CIPP liner before it is pulled between the mainroller and the clamping roller.
 23. The CIPP liner feed roller apparatusof claim 21, further comprising one or more guide rollers attached tothe support beam configured to guide the CIPP liner after it is has beenpushed away from the main roller and the clamping roller.
 24. The CIPPliner feed roller apparatus of claim 21, further comprising a balanceroller attached to the support beam and wherein the balance roller isconfigured in parallel to the main roller and is positioned to contactthe CIPP liner after it has been pushed away from the main roller andthe clamping roller.
 25. The CIPP liner feed roller apparatus of claim21, further comprising a plurality of folding rollers configured to curlthe CIPP liner before it is pulled between the main roller and theclamping roller, wherein the plurality of folding rollers are attachedto the support beam.
 26. The CIPP liner feed roller apparatus of claim25, wherein the CIPP liner feed roller apparatus is configured to pushthe CIPP liner away from the main roller and the clamping roller suchthat the CIPP liner will contain at least one fold.